Rationalizing the differences among hydraulic relationships using a process-based model
Rationalizing the differences among hydraulic relationships using a process-based model
The use of power law forms to describe hydraulic geometry is a classic subject with a history of over 70 years. Two distinct forms of power laws have been proposed: at-a-station hydraulic geometry (AHG) and downstream hydraulic geometry (DHG). Although the utility of these semiempirical expressions is widely recognized, they remain poorly understood in terms of the mechanisms underlying the differences between AHG and DHG, as well as the variability among different systems. In this study, we attempt to address these basic issues. Two hypotheses are proposed: (a) the different geomorphic relationships represented by AHG and DHG result from the control of lateral adjustment of the bank and flow turbulence over short and long timescales, respectively; and (b) the systematic variability of the AHG and DHG exponents is related to the description of the frictional resistance. These two hypotheses are embedded in our theoretical models and lead to explicit functional forms for AHG and DHG. The verification of our hypotheses is based on a large data set consisting of over 550 b-f-m exponents and 120 power law hydraulic relations. The analysis highlights the role of uncertainties in data acquisition and theoretical/statistical explanations. In addition, the theoretical expressions of AHG also provide an explanation of at-many-stations hydraulic geometry (AMHG) in a physical sense. Overall, our work provides new insights into the fundamental theory of power laws and hydraulic geometry.
at-a-station hydraulic geometry, at-many-stations hydraulic geometry, downstream hydraulic geometry, hydraulic geometry
Xu, Fan
a74a50aa-98c4-4457-a767-f0fe8820c535
Coco, Giovanni
b5e273dc-1483-4764-9b54-d196075136e4
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
Guo, Leicheng
713f7dde-d88a-4f2c-9c66-7f9c6978ceb0
He, Qing
94baedd4-45f0-436e-83d4-4e2ebcd1bec3
Zhao, Kun
68779f85-b646-485f-a724-1c8100cfd442
Zhou, Zeng
f25e1390-6f07-4a32-9ebf-de15c07ded62
Xu, Fan
a74a50aa-98c4-4457-a767-f0fe8820c535
Coco, Giovanni
b5e273dc-1483-4764-9b54-d196075136e4
Townend, Ian
f72e5186-cae8-41fd-8712-d5746f78328e
Guo, Leicheng
713f7dde-d88a-4f2c-9c66-7f9c6978ceb0
He, Qing
94baedd4-45f0-436e-83d4-4e2ebcd1bec3
Zhao, Kun
68779f85-b646-485f-a724-1c8100cfd442
Zhou, Zeng
f25e1390-6f07-4a32-9ebf-de15c07ded62
Xu, Fan, Coco, Giovanni, Townend, Ian, Guo, Leicheng, He, Qing, Zhao, Kun and Zhou, Zeng
(2021)
Rationalizing the differences among hydraulic relationships using a process-based model.
Water Resources Research, 57 (8), [e2020WR029430].
(doi:10.1029/2020WR029430).
Abstract
The use of power law forms to describe hydraulic geometry is a classic subject with a history of over 70 years. Two distinct forms of power laws have been proposed: at-a-station hydraulic geometry (AHG) and downstream hydraulic geometry (DHG). Although the utility of these semiempirical expressions is widely recognized, they remain poorly understood in terms of the mechanisms underlying the differences between AHG and DHG, as well as the variability among different systems. In this study, we attempt to address these basic issues. Two hypotheses are proposed: (a) the different geomorphic relationships represented by AHG and DHG result from the control of lateral adjustment of the bank and flow turbulence over short and long timescales, respectively; and (b) the systematic variability of the AHG and DHG exponents is related to the description of the frictional resistance. These two hypotheses are embedded in our theoretical models and lead to explicit functional forms for AHG and DHG. The verification of our hypotheses is based on a large data set consisting of over 550 b-f-m exponents and 120 power law hydraulic relations. The analysis highlights the role of uncertainties in data acquisition and theoretical/statistical explanations. In addition, the theoretical expressions of AHG also provide an explanation of at-many-stations hydraulic geometry (AMHG) in a physical sense. Overall, our work provides new insights into the fundamental theory of power laws and hydraulic geometry.
Text
Water Resources Research - 2021 - Xu - Rationalizing the Differences Among Hydraulic Relationships Using a Process‐Based
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More information
Accepted/In Press date: 11 July 2021
e-pub ahead of print date: 22 July 2021
Additional Information:
Funding Information:
This study is supported by the National Natural Science Foundation of China (Grant Nos. 42006150, 51739005), Key Program for International S&T Cooperation Projects of China (Grant No. 2016YFE0133700).
Keywords:
at-a-station hydraulic geometry, at-many-stations hydraulic geometry, downstream hydraulic geometry, hydraulic geometry
Identifiers
Local EPrints ID: 467591
URI: http://eprints.soton.ac.uk/id/eprint/467591
ISSN: 0043-1397
PURE UUID: f196ec8b-a8e8-4e4e-acc2-f9dc5a4fcdca
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Date deposited: 14 Jul 2022 17:12
Last modified: 18 Mar 2024 02:55
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Contributors
Author:
Fan Xu
Author:
Giovanni Coco
Author:
Leicheng Guo
Author:
Qing He
Author:
Kun Zhao
Author:
Zeng Zhou
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